This is a blog for people interested in technology. I'll be posting projects and tutorials on things such as Arduino, IoT devices, Electronics, Machine Learning and whatever springs to mind.

How to Use a Light Dependent Resistor (LDR) with Arduino

Lots of projects use a Light Dependent Resistor (LDR) to sense light levels but don’t really focus on how they work.

This project shows you how to use a Light Dependent Resistor (LDR) to sense light levels, measure those levels with the Arduino and print the measurements to the Serial port.

Arduino measures Voltages on pins A0 to A5; but the LDR is a variable resistor (varying with Light). So we need to convert the varying resistance to a voltage that the Arduino can measure.

We do that by using the LDR and a Resistor in a Potential Divider circuit.

How it Works

The top of the Potential Divider is 5V; the bottom is at 0V and the middle (connected to A0) is some value between 5V and 0V that varies as the LDR resistance varies according to the light level.

As both resistors are in series the same current must flow through them both. The LDR resistance drops with light, which causes the current in both resistors to increase (I=V/R), and therefore the voltage across the other (non-LDR) increases.

So as the LDR resistance varies with Light, the Voltage at A0 will too.

Technically you can work out the Voltage on A0 as :

Va0 = 5 * R1/(R1+R2)

where Va0 is the voltage at A0 pin, R2 is the top resistor value, R1 is the bottom resistor value;

The LDR has a high value when no light is present. The value of resistance of the LDR depends on the type. In this case it’s about 10k. As the light level increases the resistance drops, which makes the current increase (by Ohm’s Law), which in turn, makes the voltage at A0 (Va0) increase.

Electrically this is what’s happening (skip this if you’re not interested in this): The LDR and resistor are in series with the applied voltage (5V), so the current flowing through them is the same (the A0 pin draws virtually zero current). So the current through the resistor is (by Ohm’s Law):

I = 5 / (R1+R2)

Now, the voltage across the resistor is applied to A0. Again, by Ohm’s Law that is:

Va0 = I * R1

Substituting the equation for I back in to this equation we get:

Va0 = 5 * R1/(R1+R2)

The Code

You can use the AnalogInOutSerial code (File -> Examples -> Analog -> AnalogInOutSerial) to measure a value on A0 and print it to the Serial Monitor.

How to Make it Better

The AnalogInOutSerial code also uses the measured sensor value to change the brightness of an LED on pin 9. Add the LED.